JP2022507883A - Exception handling method, terminal device and storage medium - Google Patents

Abstract

An abnormality handling method, a terminal device, and a computer-readable storage medium, wherein the method loads and executes a driver of the WIFI module after receiving an instruction to start the WIFI function of the terminal device, and the terminal. At least one request subflow is started in the hardware layer of the WIFI system through the framework layer of the WIFI system of the device, and if any of the request subflows fails, the driver of the WIFI module from the memory of the terminal device. Includes the step of reloading and executing the driver of the WIFI module after clearing the driver of the WIFI module from the memory, and recovering quickly when an abnormality occurs in the WIFI module by this application. can.

Description

The present application belongs to the field of communication technology and particularly relates to anomalous handling methods, terminal devices and computer readable storage media.

Currently, most mobile phones and other terminal devices are equipped with wireless LAN cards. The wireless LAN card is indeed one of the three key modules of Intel's Centrino technology-WIFI module. A transmission module and a reception module are usually installed in the wireless LAN card. When a user connects to a wireless LAN via a WIFI module on a terminal device, it scans a nearby wireless access point (Wireless Access Point, AP) and selects the scanned wireless access point as the placement AP. It is necessary to connect to the deployment AP and provide Internet services through the deployment AP.

The present application provides an anomaly handling method for accessing a wireless LAN via a WIFI module, a terminal device, and a computer-readable storage medium, whereby if an anomaly occurs in the WIFI module, it is quickly repaired. ..

According to the first aspect of the present application, there is provided a powerback-off method applied to a terminal device including a WIFI module. The method is
After receiving the command to start the WIFI function of the terminal device, the step of loading and executing the driver of the WIFI module, and
A step of initiating at least one request subflow to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device.
If any of the request subflows fails, the step of clearing the driver of the WIFI module from the memory of the terminal device and
Includes a step of reloading and executing the WIFI module driver after the WIFI module driver has been cleared from memory.

According to the second aspect of the present application
After receiving the command to start the WIFI function of the terminal device, the load execution unit for loading and executing the driver of the WIFI module, and
A request subflow start unit for initiating at least one request subflow to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device.
If any of the request subflows fails, a clear unit for clearing the driver of the WIFI module from the memory of the terminal device, and
Provided is a terminal device including a reload execution unit for reloading and executing the driver of the WIFI module after the driver of the WIFI module is cleared from the memory.

According to a third aspect of an embodiment of the present application, a terminal device including a memory, a processor, and a computer program stored in the memory and executed on the processor is provided, and the processor executes the computer program. In doing so, the steps of the method provided by the first aspect of the embodiments of the present application are realized.

According to a fourth aspect of an embodiment of the present application, a computer-readable storage medium in which a computer program is stored is provided, and when the computer program is executed by one or more processors, the present application is carried out. The steps of the method provided by the first aspect of the example are realized.

According to a fifth aspect of an embodiment of the present application, a computer program product comprising a computer program is provided, the first embodiment of the present application when the computer program is executed by one or more processors. The steps of the method provided by the above embodiment are realized.

In order to more clearly explain the technical proposal of the examples of the present application, the drawings necessary for the explanation of the examples or the prior art are briefly introduced below, and clearly, the drawings of the following description are a part of the present application. However, those skilled in the art can obtain other drawings based on these drawings without any creative effort.
It is a flowchart which realizes the exception handling method provided by the Example of this application. It is a flowchart which realizes another exception handling method provided by the Example of this application. It is a flowchart which realizes another exception handling method provided by the Example of this application. FIG. 3 is a schematic block diagram of a terminal device provided by an embodiment of the present application. FIG. 3 is a schematic block diagram of another terminal device provided by an embodiment of the present application.

The following description provides specific details, such as specific system structures, techniques, etc., to explain, but not to limit, the embodiments of the present application so that they can be fully understood. However, it should be understood by those skilled in the art that the present application can be realized even in other embodiments without these specific details. In other cases, detailed description of well-known systems, devices, circuits and methods will be omitted so that unnecessary details do not interfere with the description of this application.

As used herein and in the accompanying claims, the term "contains" refers to the presence of descriptive features, whole, steps, actions, elements, and / or components, but one or more others. It should be understood that it does not preclude the existence or addition of features, wholes, steps, actions, elements, components, and / or sets thereof.

It should be noted that the terms used herein are for illustration purposes only and are not intended to limit this application. As used herein and in the appended claims, the singular "1", "1" and "corresponding" are intended to include the plural, unless otherwise specified in the context. ..

In addition, the term "and / or" as used herein and in the accompanying claims refers to any and all possible combinations of one or more of the associated items, and these combinations. Please understand that it includes.

As used herein and in the accompanying claims, the term "if" is contextually "when" or "when" or "in response to a decision" or "discovered". Respond. " Similarly, the phrase "if determined" or "if detected" (explained condition or event) is contextually "determined" or "determined" (explained condition or event). It may be described as "responding" or "discovering" or "responding to detecting (explained condition or event)".

In order to explain the technical proposal described by this application, the following will be described with reference to specific examples.

FIG. 1 is a flowchart that realizes the exception handling method provided by the embodiment of the present application. The abnormality handling method is applied to a terminal device including a WIFI module. As shown in the figure, this method comprises the following steps 101-104.

Step 101, After receiving the command to start the WIFI function of the terminal device, the driver of the WIFI module is loaded and executed.

In the embodiment of the present application, the user can start the WIFI function of the terminal device by clicking the display screen on the terminal device, for example, a virtual button of the WIFI function is set on the terminal device such as a mobile phone, and the user. Clicks the virtual button of the WIFI function, and then sends an instruction to start the WIFI function of the terminal device via the virtual button.

After receiving the command to start the WIFI function of the terminal device, the driver of the WIFI module is loaded into the memory and executed.

As another embodiment of the present application, it is also possible to set a daemon to be started after monitoring the execution of the driver of the WIFI module for the driver of the WIFI module. Other functions of the daemon will be described later.

Step 102: Initiate at least one billing subflow to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device.

In the embodiment of the present application, when the terminal device accesses the wireless LAN via the WIFI module to perform the Internet service, the following flow is required and will be described as follows. Launch, scan, view scanned wireless access points, deploy wireless access points, connect wireless access points, get IP addresses, use the Internet.

When scanning, the WIFI system framework layer needs to initiate a scan request to the WIFI system hardware layer, so at connection time the WIFI system framework layer needs to initiate a connection request to the WIFI system hardware layer. Therefore, in the embodiment of the present application, the flow between initiating the scan request and the connection request can be referred to as a scan request subflow. The process from starting a continuous request to continuing to the wireless access point can be called a connection request subflow. The request subflow includes a scan request subflow and a connection request subflow. If the scan request subflow is successful, you can run the connection request subflow.

Step 103, if any of the request subflows fails, the driver of the WIFI module is cleared from the memory of the terminal device.

In the embodiment of the present application, if either the connection request subflow or the connection request subflow fails, it is necessary to clear the driver of the WIFI module from the memory.

As an example of connecting to a request subflow, if the framework layer does not receive the scan response returned by the hardware layer within the first preset time after initiating a scan request to the hardware layer. , Determines that the current scan request subflow has failed and clears the WIFI module driver from memory.

Of course, in actual execution, the single scan request subflow may not necessarily have received the scan response returned by the hardware layer for other reasons, not necessarily an error loading the driver into memory. If the framework layer does not receive the scan response returned by the hardware layer within the first preset time after initiating a scan request to the hardware layer, the framework layer will continue to be the hardware. After initiating a scan request to the layer and starting scan requests continuously more than a certain number of times, it is determined that the current scan request subflow has failed and the driver of the WIFI module is cleared from the memory. You may set it. The scan response is information indicating that the hardware layer of the WIFI system has received the scan request returned to the framework layer.

Step 104, After the driver of the WIFI module is cleared from the memory, the driver of the WIFI module is reloaded and executed.

In the embodiment of the present application, it is necessary to reload and execute the driver of the WIFI module after the driver of the WIFI module is removed from the memory. In this way, if the driver of the WIFI module is reloaded and executed, the error when the driver is previously loaded and executed can be cleared.

As described above, a daemon can be set in the driver of the WIFI module, and the driver can automatically restart the driver when an abnormal termination of the driver is found. In the embodiment of the present application, the driver is cleared from the memory because the request subprocessor has failed, which may be treated as the case where the driver terminates abnormally. Therefore, the daemon is the driver of the WIFI module. After monitoring that the WIFI module has been cleared from memory, it can be triggered to reload and execute the driver for the WIFI module.

In actual execution, if there is something wrong with the WIFI module, the WIFI function may not be available due to a long scan request or connection request, which will affect the user's experience, and in severe cases, restart the terminal device. May cause. In the embodiment of the present application, after determining that the WIFI function has become abnormal, a voluntary and real-time recovery is attempted, for example, if the driver is cleared from the memory and reloaded and executed, the previous driver is loaded. It is possible to clear the error when executing.

FIG. 2 is a flowchart that realizes another exception handling method provided by the embodiment of the present application, and this exception handling method is applied to a terminal device including a WIFI module. As shown in the figure, this method can include the following steps 201-204.

Step 201, after receiving the command to start the WIFI function of the terminal device, the driver of the WIFI module is loaded and executed.

Step 202, start a scan request subflow to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device.

Steps 201 to 202 are the same as the contents of steps 101 to 102. Specifically, the description of steps 101 to 102 can be referred to, and the description thereof will be omitted here.

Step 203, the scan response from the hardware layer is received within the first preset time after the framework layer initiates the scan request to the hardware layer, and the framework layer initiates the scan request. If the scan result from the hardware layer is not received within the second preset time later, the scan request subflow is continuously sent to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device. Start.

Step 204, if any of the scan request subflows transmitted consecutively a preset number of times fails, the driver of the WIFI module is cleared from the memory.

In the embodiments of the present application, the purpose of the scan request subflow is to obtain a list of scanned radio access points. As described in the embodiment shown in FIG. 1, if the scan response returned from the hardware layer is not received, the hardware layer may not have received the scan request transmitted from the framework layer. It has been shown to be capable and may not scan the hardware layer. Further, since a communication error has occurred between the hardware layer and the framework layer, communication between the framework layer and the hardware layer cannot be performed normally, so that the hardware layer can access the wireless access point. It may also indicate that the scan result cannot be returned to the framework layer despite the scan. Therefore, if the scan response returned from the hardware layer is not received within the first preset time after the framework layer initiates a scan request to the hardware layer, the scan request subflow has failed. Is shown, even though the framework layer received the scan response returned from the hardware layer within the first preset time after initiating a scan request to the hardware layer. If does not receive the scan result returned from the hardware layer within the second preset time after initiating the scan request to the hardware layer, it indicates that the scan request subflow is currently failing. A successful scan request subflow is shown only if a list of scanned wireless access points, ie scan results, can be obtained.

In the actual execution, whether the scan response is not received or the scan result is not received, it may be due to an accidental abnormality, and the memory of the terminal device loads the driver. It does not indicate that an error has occurred when executing. Therefore, the scan response returned from the hardware layer is received within the first preset time after the framework layer starts the scan request to the hardware layer, and the framework layer scans the hardware layer. If the can result returned from the hardware layer is not received within the second preset time after initiating the request, the hardware of the WIFI system continues through the framework layer of the WIFI system of the terminal device. A scan request subflow may be started on the layer, and if any of the scan request subflows transmitted consecutively a preset number of times fails, the driver of the WIFI module is cleared from the memory.

When restarting the scan subflow, it is possible to allow the continuous transmission of the preset number of scan request subflows until all the scan request subflows transmitted consecutively preset times fail. can. If any of the scan request subflows are successful, you can enter the connection request subflow.

As another embodiment of the present application, the scan response returned from the hardware layer is received and the scan is performed within the first preset time after the framework layer initiates a scan request to the hardware layer. If the scan result returned from the hardware layer is not received within the third preset time when the response is received, it is determined that the current scan request subflow has failed and the driver of the WIFI module is cleared from the memory. ..

In the embodiment of the present application, a second preset time can be set, and the starting point of the second preset time is the time when the framework layer starts a scan request to the hardware layer, and the third preset time. Can also be set, and the starting point of the third preset time is the time for receiving the scan response.

Step 205, After the driver of the WIFI module is cleared from the memory, the driver of the WIFI module is reloaded and executed.

This step is consistent with the content of step 104, and the description of step 104 can be specifically referred to, and the description thereof will be omitted here.

FIG. 3 is a flowchart that realizes another exception handling method provided by the embodiment of the present application, and this exception handling method is applied to a terminal device including a WIFI module. As shown in the figure, this method can include the following steps 301-309.

Step 301, after receiving the command to start the WIFI function of the terminal device, the driver of the WIFI module is loaded and executed.

Step 302, start a scan request subflow to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device.

Step 303, When the scan request subflow is successful, the connection request subflow is started to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device.

Step 304, After the framework layer initiates a connection request to the hardware layer, it is determined whether the current connection request is the first connection request after initiating the WIFI function this time.

Step 305 In the case of the first connection request, the current time is set as the current connection request start time, and the state of the hardware layer is monitored.

Step 306 If it is not the first connection request, it is determined whether or not the time interval between the current time and the time when the previous connection request was started is smaller than the preset time interval.

Step 307, if the time interval between the current time and the time when the last connection request was started is smaller than the preset time interval, the current time is recorded as the current connection request start time and the state of the hardware layer is monitored. do.

In step 308, when it is monitored that the state of the hardware layer is a preset state, it is determined that the connection request subflow has failed, and the driver of the WIFI module is cleared from the memory.

Step 309, After the driver of the WIFI module is cleared from the memory, the driver of the WIFI module is reloaded and executed.

In the embodiment of the present application, if the scan request subflow is successful, the connection request subflow is continued to be executed. When executing the connection request subflow, after one connection request subflow fails, the driver of the WIFI module is cleared from the memory, the driver of the WIFI module is cleared from the memory, and then the driver of the WIFI module is restarted. Can be loaded and run. That is, after the first connection request subflow fails, the scan request subflow and the connection request subflow are re-executed and the first connection request subflow fails due to an error that occurred in one connection process. The continuous request subflow may be executed again, and if all of the multiple connection request subflows fail, the driver of the WIFI module can be cleared from the memory after the driver of the WIFI module is erased from the memory. , Reload and execute the driver of the WIFI module. Perform the scan request subflow and the connection request subflow in sequence.

In the examples of the present application, steps 304 to 309 will be described as follows. If it is monitored that the state of the hardware layer is a preset state after each connection request is sent, it is determined that the connection request subflow has failed and the driver of the WIFI module is cleared from the memory. .. That is, regardless of the number of times the connection request subflow is executed, as long as the state of the hardware layer is monitored to be the preset state, the driver of the WIFI module is cleared from the memory, and the driver is reloaded and executed. do.

According to the description of step 304 and step 309, the scan request subflow and the connection request subflow may be executed repeatedly. Therefore, the termination condition may be set as follows. In any of the connection subflows, is the time interval between the current time and the previous connection request start time less than the preset time interval after the framework layer initiates a connection request to the hardware layer? Judge whether or not. If the time interval between the current time and the time when the last connection request was started is greater than or equal to the preset time interval, it indicates that there may be an abnormality in the hardware layer. It is not necessary to clear, load, or execute the driver in the memory, and the WIFI function of the terminal device can be terminated.

Of course, in actual execution, other termination conditions such as the following may be set. If the WIFI module does not successfully connect to the wireless access point within the fourth preset time after starting the WIFI function of the terminal device, the WIFI function of the terminal device is terminated.

As another embodiment of the present application, the step of monitoring the state of the hardware layer includes the following steps.

If the state of the hardware layer is being switched, it waits for the switching result.

When the state switching of the hardware layer is completed, the monitored state of the hardware layer is the switching result.

In the embodiment of the present application, one piece of information cannot be processed at the same time unless the same state is maintained between the framework layer and the hardware layer (lower cheap side or supportant), and the state of the hardware layer is It may be a connection or it may be blank. If it is connected, it indicates that it has connected to the wireless access point, and if it is blank, it indicates that it has not connected to the wireless access point. Of course, the state of the hardware layer may be being switched, and if the current state of the hardware layer is still being switched and the current information is only pending for a short period of time, there is currently an anomaly. You may wait for the switching result. The preset state indicates a blank state.

As another embodiment of the present application, before clearing the driver of the WIFI module from memory,
A step of starting the virtual execution environment and executing the driver of the WIFI module currently loaded in the memory in the virtual execution environment.
In the virtual execution environment, if the driver of the WIFI module fails to execute, the step of clearing the driver of the WIFI module from the memory is further included.

In the embodiments of the present application, it is possible to determine whether or not there is an abnormality in the driver currently loaded and executed in the memory before each time the driver of the WIFI module is cleared from the memory, and the driver is currently loaded and executed. If there is a certain abnormality in the driver, the driver can be cleared from the memory, and the driver can be reloaded and executed. If there is nothing wrong with the driver that is currently being loaded and executed, it clearly makes no sense to clear it from memory and re-load and execute it. Therefore, when the virtual execution environment is started and the driver of the WIFI module currently loaded in the memory can be executed in the virtual execution environment, and the execution of the driver of the WIFI module fails in the virtual execution environment. , It is shown that there is something wrong with the driver currently loaded and executed in the memory, and the driver of the WIFI module is cleared from the memory.

As another embodiment of the present application, when the driver of the WIFI module is successfully executed in the virtual execution environment, the driver of the WIFI module is re-executed and the driver of the WIFI module is re-executed via the framework layer of the WIFI system of the terminal device. At least one request subflow is started in the hardware layer of the WIFI system.

If the driver of the WIFI module is successfully executed in the virtual execution environment, it is indicated that the driver currently loaded in the memory is normal, and it may have been caused by some reason in the execution process. At least one in the hardware layer of the WIFI system by the WIFI system framework of the terminal device by re-running the driver of the WIFI module without having to clear from memory and reload the operation of the driver. The request subflow needs to be started again.

Before starting the virtual execution environment, a step of presetting the virtual execution environment is further included. The step of presetting the virtual execution environment is
In the virtual execution environment, the step of setting the virtual WIFI module based on the hardware parameters of the WIFI module, and
Response information is set for the virtual WIFI module based on the data interaction between the framework layer and the hardware layer.

As another embodiment of the present application, after initiating at least one request subflow to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device, further.
If all the request subflows are successful, the Internet is used via the wireless access point where the connection is requested in the connection request subflow.

In the embodiments of the present application, the success of all request subflows indicates that both the scan request subflow and the connection request subflow were successful, indicating that they were connected to one wireless access point. You can connect to the Internet via the wireless access point for which connection was requested in the connection request subflow.

The sequence number of each step in the above embodiment does not mean the execution order, and the execution order of each process is determined by its function and intrinsic logic, and the execution process of the embodiment of the present application should be limited. Please understand that there is no such thing.

FIG. 4 is a schematic block diagram of a terminal device provided by one embodiment of the present application, showing only parts relevant to the embodiments of the present application for ease of description.

The terminal device 4 may be a software unit, a hardware unit, or a unit combined with software built in a terminal device such as a mobile phone, a tablet, or a notebook, or the mobile phone or tablet as a unique strap. , Can also be integrated in terminal devices such as notebooks.

This terminal device 4 is
After receiving the command to start the WIFI function of the terminal device, the load execution unit 41 for loading and executing the driver of the WIFI module, and
A request subflow start unit 42 for initiating at least one request subflow to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device.
If any of the request subflows fails, the clear unit 43 for clearing the driver of the WIFI module from the memory of the terminal device, and
It includes a reload execution unit 44 for reloading and executing the driver of the WIFI module after the driver of the WIFI module is cleared from the memory.

As another embodiment of the present application, the request subflow includes a scan request subflow and a connection request subflow.

As another embodiment of the present application, the request subflow initiation unit 42 is
A scan subflow module 421 for initiating a scan request subflow to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device.
Includes a connection request subflow module 422 for initiating a connection request subflow to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device after the scan request subflow is successful.

As another embodiment of the present application, when a scan request subflow is initiated into the hardware layer of the IFI system via the framework layer of the WIFI system of the terminal device, the clear unit 43 further comprises.
If the framework layer does not receive the scan response returned by the hardware layer within the first preset time after initiating the scan request to the hardware layer, then the current scan request subflow has failed. It is used to determine and clear the driver of the WIFI module from memory.

As another embodiment of the present application, when a scan request subflow is initiated into the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device, the clear unit 43 further comprises.
The scan response returned from the hardware layer is received within the first preset time after the framework layer initiates a scan request to the hardware layer, and the framework layer makes a scan request to the hardware layer. If the can result returned from the hardware layer is not received within the second preset time after the start, it is determined that the current scan request subflow has failed and the driver of the WIFI module is cleared from the memory. Used for.

As another embodiment of the present application, when a scan request subflow is initiated into the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device, the clear unit 43 further comprises.
Within the first preset time after the framework layer initiates a scan request to the hardware layer, the scan response returned from the hardware layer is received, and within the third preset time after receiving the scan response. If the scan result returned from the hardware layer is not received, it is determined that the current scan request subflow has failed, and it is used to clear the driver of the WIFI module from the memory.

As another embodiment of the present application, the scan subflow module 421 is further described.
Before clearing the driver of the WIFI module from the memory, the scan request subflow transmitted a preset number of times in a row continues to pass through the framework layer of the WIFI system of the terminal device until the scan request subflow fails. Used to initiate a scan request subflow to the hardware layer of a WIFI system.

As another embodiment of the present application, when a connection request subflow is initiated to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device, the clear unit 43 further comprises.
After the framework layer initiates a connection request to the hardware layer, it is determined whether the current connection request is the first connection request.
In the case of the first connection request, the current time is recorded as the current connection request start time, and the state of the hardware layer is monitored.
When it is monitored that the state of the hardware layer is a preset state, it is determined that the connection request subflow has failed, and it is used to clear the driver of the WIFI module from the memory.

As another embodiment of the present application, when a connection request subflow is initiated to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device, the clear unit 43 further comprises.
If it is not the first connection request, it is determined whether the time interval between the current time and the previous connection request start time is smaller than the preset time interval.
If the time interval between the current time and the previous connection request start time is less than the preset time interval, record the current time as the current connection request start time and monitor the hardware layer status.
When it is monitored that the state of the hardware layer is a preset state, it is determined that the connection request subflow has failed, and it is used to clear the driver of the WIFI module from the memory.

As another embodiment of the present application, the clear unit 43 is further described.
When the state of the hardware layer is being switched, it is used to wait for the switching result.
When the state switching of the hardware layer is completed, the monitored state of the hardware layer is the switching result.

As another embodiment of the present application, the terminal device 4 is
A daemon setting unit 45 for setting a daemon in the driver of the WIFI module.
The daemon starts after monitoring the execution of the driver of the WIFI module.
The daemon includes a daemon configuration unit 45 that triggers to reload the driver of the WIFI module after monitoring that the driver of the WIFI module has been cleared from memory.

As another embodiment of the present application, the reload execution unit 44 further comprises.
Once the daemon has monitored that the driver for the WIFI module has been cleared from memory, it is used to trigger the reload and execution of the driver for the WIFI module.

As another embodiment of the present application, the terminal device 4 is further described.
A virtual execution unit 46 for starting a virtual execution environment and executing the driver of the WIFI module currently loaded in the memory in the virtual execution environment before clearing the driver of the WIFI module from the memory.
In the virtual execution environment, when the driver of the WIFI module fails to execute, the clear unit 43 for clearing the driver of the WIFI module from the memory is included.

As another embodiment of the present application, the reload execution unit 44 further comprises.
After executing the driver of the WIFI module currently loaded in the memory in the virtual execution environment, if the driver of the WIFI module succeeds in the execution in the virtual execution environment, the driver of the WIFI module is re-executed and described. It is used to initiate at least one request subflow to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device.

As another embodiment of the present application, the terminal device 4 is further described.
In the virtual execution environment, the virtual execution environment setting unit for setting the virtual WIFI module based on the hardware parameters of the WIFI module is included.
Response information is set in the virtual WIFI module based on the data interaction between the framework layer and the hardware layer.

As another embodiment of the present application, the terminal device 4 is
If the WIFI module does not succeed in connecting to the wireless access point within the fourth preset time after starting the WIFI function of the terminal device, the WIFI termination unit for terminating the WIFI function of the terminal device is included. ..

As another embodiment of the present application, the terminal device 4 is further described.
If all the request subflows are successful, the connection request subflow includes an Internet service unit for using the Internet through the wireless access point requesting the connection.

For the convenience and conciseness of the explanation, the above functions will be explained by giving examples only by the division of each function unit and module above, and in actual execution, the above functions will be completed by different function units and modules according to the needs. It should be clearly understood by those skilled in the art to divide the internal structure of the terminal device into different functional units or modules so that they can be assigned, i.e., complete all or part of the functions described above. Is. Each functional unit and module of the embodiment may be integrated into one processing unit, each unit may exist individually and physically, or two or more units may be integrated into one unit. Is also good. The integrated unit may be realized by adopting the form of hardware, or may be realized by adopting the form of software function unit. Further, the specific names of the functional units and modules are also intended to make it easy to distinguish them from each other, and are not intended to limit the scope of protection of the present application. For the specific operation process of the unit and the module in the terminal device, the corresponding process of the embodiment of the above method may be referred to, and the description thereof will be omitted here.

FIG. 5 is a schematic block diagram of the terminal apparatus provided by another embodiment of the present application, and as shown in FIG. 5, the terminal apparatus 5 of the present embodiment has one or more processors 50 and a memory 51. , And a computer program 52 that is stored in memory 51 and can be executed on the processor 50. The processor 50 realizes the steps in the embodiment of each method when executing the computer program 52. For example, steps S101 to S104 shown in FIG. 1 are realized. Alternatively, when the computer program 52 is executed, the processor 50 realizes the functions of each module / unit in the embodiment of the terminal device, for example, the functions of the modules 41 to 44 shown in FIG.

Illustratively, the computer program 52 may be divided into one or more modules / units, the one or more modules / units stored in memory 51 and executed by the processor 50. Complete this application. The one or more modules / units may be a set of computer program instruction segments capable of completing a particular function for describing the execution process of the computer program 52 in the terminal device 5. For example, the computer program 52 may be divided into a load execution unit, a request subflow start unit, a clear unit, and a reloading operation unit. Illustratively
The load execution unit is used to load and execute the driver of the WIFI module after receiving an instruction to start the WIFI function of the terminal device.
The request subflow start unit is used to initiate at least one request subflow to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device.
The clearing unit is used to clear the driver of the WIFI module from memory if any of the request subflows fails.
The reload execution unit is used to reload and execute the driver of the WIFI module after the driver of the WIFI module is cleared from the memory.

For other units or modules, the description of the embodiment shown in FIG. 4 may be referred to, and the description thereof will be omitted here.

The terminal device includes, but is not limited to, a processor 50 and a memory 51. Those skilled in the art can understand that FIG. 5 is merely an example of the terminal device 5 and is not limited to the terminal device 5. More or less parts than FIG. 5, or a combination of some parts, or different parts may be included, for example, the terminal device may include an input device, an output device, a network access device, a bus, a touch screen, and the like.

The processor 50 may be a central processing unit (CPU), another general-purpose processor, a digital signal processor (DSP), a dedicated integrated circuit (Application Specific Integrated Circuit, ASIC), and an ASIC. It may be a programmable gate array (Field-Programmable Gate, FPGA) or other programmable logic device, discrete gate or transistor logic device, discrete hardware component, and the like. The general purpose processor may be a microprocessor, or the processor may be any conventional processor or the like.

The memory 51 may be an internal storage unit such as a hard disk or a memory of the terminal device 5. The memory 51 is an external storage device of the terminal device 5, for example, a connected hard disk mounted on the terminal device 5, a smart memory card (SmartMedia Card, SMC), a security digital (SD) card, and the like. It may be a flash card (FlashCard) or the like. Further, the memory 51 may include an internal storage unit and an external storage device of the terminal device 5. The memory 51 is used to store the computer program and other programs and data required for the terminal device. The memory 51 is also used to temporarily store the output data or the output data.

Those skilled in the art will appreciate that the various example units and algorithm steps described in the embodiments disclosed herein can be implemented in electronic hardware, or in combination with computer software and electronic hardware. .. Whether these functions are performed in hardware or software is determined by the specific application and design constraints of the proposed technology. One of ordinary skill in the art may use different methods to achieve the described functionality for each particular application, but such realization should be considered beyond the scope of this application. do not have.

It should be understood that in the examples provided by this application, the disclosed terminal devices and methods can be realized by other methods. For example, the embodiment of the terminal device described above is merely schematic, for example, the division of the module or unit is only the division of the logical function, and when it is actually realized, it is another division method. It may be, for example, a plurality of units or components may be combined or integrated into another system. Or some features may be ignored or may not be performed. Second, the coupling or direct coupling or communication connection between the displayed or discussed interactions may be an indirect coupling or communication connection by some interface, device or unit, electrical, mechanical or other. It may be in the form of.

The unit described as a separate device may be physically separated, and the device displayed as a unit may or may not be a physical unit, that is, it may be located in one place. Alternatively, it may be distributed in a plurality of network units. The purpose of the proposed embodiment can be realized by selecting some or all of the units in the actual needs.

Further, each functional unit in each embodiment of the present application may be integrated into one processing unit, each unit may be physically present individually, or two or more units may be one unit. May be integrated into. The integrated unit may be realized by adopting the form of hardware or may be realized by adopting the form of software function unit.

The integrated modules / units are implemented in the form of software functional units and can be stored on a computer-readable storage medium when sold or used as an independent product. Based on this understanding, the present application can be completed by instructing the relevant hardware via a computer program to realize all or part of the flow of the method of the above embodiment. The computer program is stored in a readable storage medium, and when the computer program is executed by the processing device, the steps of the embodiments of the various methods can be realized. Here, the computer program may include computer program code, which may be in source code format, object code format, executable file, or some intermediate format. The computer-readable storage medium is any entity or device capable of carrying the computer program code, recording medium, USB memory, portable hard disk, magnetic disk, optical disk, computer memory, read-only memory (ROM, Read-Only Memory). , Random access memory (RAM, Random Access Memory), electric carrier signal, telecommunications signal, software distribution medium and the like can be included. The content contained in the computer-readable storage medium can be appropriately increased or decreased according to the requirements of legislation and patent practice within the jurisdiction. For example, in some jurisdictions, legislation and patents Based on practice, computer readable storage media do not include electrical carrier signals and electrical signals.

In the above examples, the description of each embodiment has its own weight, and the parts not described in detail or described in the examples may refer to the related explanations of the other examples.

The above embodiments are used only to illustrate the technical proposals of the present application and are not intended to limit them. Although the present application has been described in detail with reference to the above embodiments, those skilled in the art may still be able to modify the technical proposals described in each of the above embodiments, or to equilibrate some technical features. It can be replaced, however, that these amendments or replacements should include the essence of this technical proposal within the scope of protection of this application without departing from the spirit and scope of the technical proposal of each embodiment of this application. Please understand.

Claims (20)

It is an exception handling method and is applied to a terminal device including a WIFI module.
After receiving the command to start the WIFI function of the terminal device, the step of loading and executing the driver of the WIFI module, and
A step of initiating at least one request subflow to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device.
If any of the request subflows fails, the step of clearing the driver of the WIFI module from the memory of the terminal device and
A step of reloading and executing the WIFI module driver after the WIFI module driver has been cleared from memory.
An anomaly handling method characterized by this. The request subflow is
Including scan request subflow and connection request subflow,
The exception handling method according to claim 1. The step of initiating at least one request subflow to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device is:
A step of initiating a scan request subflow to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device.
A step of initiating a connection request subflow to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device after the scan request subflow is successful.
The exception handling method according to claim 2. When a scan request subflow is started in the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device, and if any of the request subflows fails, the memory of the terminal device of the WIFI module The step to clear the driver is
If the framework layer does not receive the scan response returned by the hardware layer within the first preset time after initiating the scan request to the hardware layer, then the current scan request subflow has failed. Includes steps to determine and clear the driver for the WIFI module from memory.
The exception handling method according to claim 2. When a scan request subflow is started in the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device, and if any of the request subflows fails, the memory of the terminal device of the WIFI module The step to clear the driver is
The scan response returned from the hardware layer is received within the first preset time after the framework layer initiates a scan request to the hardware layer, and the framework layer makes a scan request to the hardware layer. If the can result returned from the hardware layer is not received within the second preset time after starting, it is determined that the current scan request subflow has failed and the driver of the WIFI module is cleared from the memory. Including the steps to do,
The exception handling method according to claim 4. When a scan request subflow is started in the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device, and if any of the request subflows fails, the memory of the terminal device of the WIFI module The step to clear the driver is
Within the first preset time after the framework layer initiates a scan request to the hardware layer, the scan response returned from the hardware layer is received, and within the third preset time after receiving the scan response. If the scan result returned from the hardware layer is not received, it is determined that the current scan request subflow has failed, and the step of clearing the driver of the WIFI module from the memory is included.
The exception handling method according to claim 4. The WIFI continues through the framework layer of the WIFI system of the terminal device until any of the scan request subflows transmitted consecutively a preset number of times before clearing the driver of the WIFI module from the memory fails. Including additional steps to initiate a scan request subflow in the hardware layer of the system,
The exception handling method according to claim 5 or 6. When starting a connection request subflow to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device, if any of the request subflows fails, the memory of the terminal device of the WIFI module The step to clear the driver is
After the framework layer initiates a connection request to the hardware layer, a step of determining whether the current connection request is the first connection request and
In the case of the first connection request, the step of recording the current time as the current connection request start time and monitoring the state of the hardware layer, and
If it is monitored that the state of the hardware layer is a preset state, it includes a step of determining that the connection request subflow has failed and clearing the driver of the WIFI module from the memory.
The exception handling method according to claim 2. After determining if the current connection request is the first connection request
If it is not the first connection request, the step of determining whether the time interval between the current time and the previous connection request start time is smaller than the preset time interval, and
If the time interval between the current time and the previous connection request start time is less than the preset time interval, record the current time as the current connection request start time and monitor the hardware layer status.
If it is monitored that the state of the hardware layer is a preset state, it further includes a step of determining that the connection request subflow has failed and clearing the driver of the WIFI module from memory.
The exception handling method according to claim 8. The step to monitor the state of the hardware layer is
When the state of the hardware layer is being switched, the step of waiting for the switching result and
When the state switching of the hardware layer is completed, the monitored step including the step in which the state of the hardware layer is the switching result is included.
The exception handling method according to claim 8 or 9. After the WIFI module driver has been cleared from memory, before reloading and running the WIFI module driver
The step of setting the daemon in the driver of the WIFI module,
A step to be started after the daemon setting unit monitors the execution of the driver of the WIFI module.
The daemon further comprises a step of triggering to reload the driver of the WIFI module after monitoring that the driver of the WIFI module has been cleared from memory.
The exception handling method according to claim 1. After the WIFI module driver has been cleared from memory, the step of reloading and executing the WIFI module driver is:
The daemon comprises a step of triggering to reload and execute the driver of the WIFI module after monitoring that the driver of the WIFI module has been cleared from memory.
The exception handling method according to claim 11. Before clearing the WIFI module driver from memory
A step of starting the virtual execution environment and executing the driver of the WIFI module currently loaded in the memory in the virtual execution environment.
Further including, in the virtual execution environment, a step of clearing the driver of the WIFI module from the memory when the driver of the WIFI module fails to execute.
The exception handling method according to claim 1. After executing the driver of the WIFI module currently loaded in the memory in the virtual execution environment,
If the driver of the WIFI module is successfully executed in the virtual execution environment, the driver of the WIFI module is re-executed and at least to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device. Further including the step of initiating one request subflow,
13. The exception handling method according to claim 13. Before starting the virtual execution environment,
In the virtual execution environment, the step of setting the virtual WIFI module based on the hardware parameters of the WIFI module, and
Further comprising: setting response information in the virtual WIFI module based on the data interaction between the framework layer and the hardware layer.
13. The exception handling method according to claim 13. After receiving the command to start the WIFI function of the terminal device,
Further including a step of terminating the WIFI function of the terminal device if the WIFI module does not successfully connect to the wireless access point within the fourth preset time after starting the WIFI function of the terminal device.
The abnormality handling method according to any one of claims 1 to 15, wherein the abnormality handling method is characterized by the above. After initiating at least one request subflow to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device.
If all request subflows are successful, the connection request subflow further includes the step of using the Internet through the wireless access point requesting a connection.
The abnormality handling method according to any one of claims 2 to 15, wherein the exception handling method is described. It ’s a terminal device,
After receiving the command to start the WIFI function of the terminal device, the load execution unit for loading and executing the driver of the WIFI module, and
A request subflow start unit for initiating at least one request subflow to the hardware layer of the WIFI system via the framework layer of the WIFI system of the terminal device.
If any of the request subflows fails, a clear unit for clearing the driver of the WIFI module from the memory of the terminal device, and
Includes a reload execution unit for reloading and executing the WIFI module driver after the WIFI module driver has been cleared from memory.
A terminal device characterized by that. A terminal device containing a memory, a processor, and a computer program stored in the memory and executed on the processor.
The processor realizes the step of the method according to any one of claims 1 to 17 when executing the computer program.
A terminal device characterized by that. A computer-readable storage medium
A computer program is stored in the computer-readable storage medium, and the computer program realizes the step according to any one of claims 1 to 17 when executed by one or a plurality of processors. do,
A computer-readable storage medium characterized by that.

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